Abstract: A voltage converter is provided in which a first terminal (A) and a second terminal (B) are provided, each coupled to a switching means, the switching means is coupled to respective terminals for connecting a first capacitor (C1), a second capacitor (C2) and a third capacitor (C3), and the voltage converter is configured for being operated in first and second modes of operation each comprising at least three phases, and in which the three capacitors (C1, C2, C3) are inserted in series connection (S) between the first terminal (A) and a reference potential terminal (10) in one phase, and in each of the two other phases a first path and a second path (P1, P2) are provided in each case in parallel connection with at least one of the three capacitors (C1, C2, C3) related to the second terminal (B).

Abstract: A circuit arrangement (1) for driving an electrical load (13) comprises a first and a second terminal (2, 3) for feeding a first and a second control signal (S1, S2), a first output (23), to which an electrical load (13) can be coupled, a current source (9), which is coupled to the first output (23), and a control device (5). The control device is coupled to the first and the second terminal (2, 3) and comprises a programming circuit (6) and a trigger circuit (7), which are each coupled on the output side to a control input of the current source (9).

Abstract: A control circuit for control of light-emitting diodes has a first LED string (50) with at least one LED (51, 52, 53) and a first supply device (1) for supply of current to the first LED string (50). The supply device (1) has a control input (10) for delivery of a first control signal (CTL) and is provided for delivery, as desired, of a first supply current (IV1) or a second supply current (IV2) in dependence on the first control signal (CTL). The first and the second control currents (IV1, IV2) are non-zero.

Abstract: A circuit arrangement for controlling at least one light source comprises a photodetector (2), a sampling circuit (6) for selectively sampling a photodetector signal (lin2) generated by the photodetector (2) as a function of a first and a second light source (10, 12), and a control unit (5), which is coupled on the input side to the sampling circuit (6). The circuit arrangement further comprises a first power-supply source (7), which is coupled to the control unit (5) and is designed for controlling at least one parameter of a first light source (12), and at least one second power-supply source (11), which is coupled to the control unit (5) and is designed for controlling at least one parameter of a second light source (12). The circuit arrangement is suitable, for example, for RGB lighting.

Abstract: A modulation arrangement comprises an input (E) for supplying a data signal (DS), a pre-modulator (VMod) that is coupled to the input (E) and features a clock pulse input (TEV) for supplying a pre-clock pulse (VT), a main modulator (HMod) that is coupled to the pre-modulator (VMod) on the input side and comprises a clock pulse input (TEH) for supplying a main clock pulse (HT), as well as an output for providing a modulated control signal (ST), and a switchable current source (Q, S) for providing a current (IS) that is controlled by the modulated control signal (ST) at an output (A) of the modulation arrangement. Furthermore, a method for providing a modulated control signal is disclosed.

Abstract: A converter arrangement includes a converter device (200) with a clocked operating mode and a non-clocked operating mode, having a signal input (Si), a control input (Se), and a signal output (So), and a control device (100) for controlling the converter device (200) with a control signal of a constant frequency and at least minimal pulse length in the clocked operating mode. The control device (100) is coupled to the control input (Se) of the converter device (200), and an input of the control device (100) is coupled to the signal output (So) of the converter device (200). An input (1) of the converter arrangement supplies a signal to be converted, that is coupled to the signal input (Si) of the converter device (200). For providing a converted signal, the converter arrangement has an output (2) that is coupled to the signal output (So). Furthermore, a corresponding method for preparing a converted signal is disclosed.

Abstract: A circuit arrangement (10) for driving an electrical load (2) comprises an input (11) for feeding a power-supply voltage (Vs) with an AC component and an output (13) for providing an output signal (Sout) for driving a connectable electrical load (2). The circuit arrangement (10) further comprises a frequency processing circuit (20) for providing a reference frequency (f1) as a function of the AC component, and a demodulator (60) with a first input (61) for feeding the reference frequency (f1), with a second input (62) that is coupled to the input (11) of the circuit arrangement (10), and with an output (63) that is coupled to the output (13) of the circuit arrangement (10).

Abstract: A current source arrangement is specified, in which at least one branch, comprising a current source (1) and means (2) for the connection of an electrical load (3), is provided. A comparator (5) with transistor (7) connected downstream is connected to a voltage tapping node (4) of said branch. The transistor (7) is connected to a common signal line (8), which is in turn connected to a feedback input of a DC voltage regulator (10). The arrangement can be extended with any number of further branches given a common signal line (8). The current source arrangement proposed is suitable in particular for supplying a plurality of LED array segments for illumination applications and displays.

Abstract: A power supply arrangement is specified in which a capacitor with a low internal resistance, in particular a supercap (3), is connected via a means for charging (4) to an input (1) and via a load current regulator (9) to a connecting means (7) for an electrical load (8). Together with a feedback path, a control loop is formed for the load current through the electrical load (8). It is therefore possible to allow flash operation in applications such as mobile telephones with rechargeable batteries with a high internal resistance, with provision for high energy utilization from the capacitor, with controlled discharging with a regulated current.

Abstract: A circuit arrangement for converting an alternating voltage (U-IN) into a rectified voltage (U-OUT) comprises a first transistor (40) whose first terminal (41) is coupled to an input terminal (1) of the circuit arrangement for feeding in the alternating voltage (U-IN), and whose second connection (42) is coupled to an output terminal (5) of the circuit arrangement for delivery of the rectified voltage (U-OUT). The circuit arrangement further comprises a control circuit (20) which is coupled on its input side to the first and second terminals (41, 42) of the first transistor (40), and which is coupled on its output side to the control terminal (43) of the first transistor (40) for the supply of a first control signal (U-S1) to the first transistor (40). The control circuit is designed to set the first control signal (U-S1) depending on a first voltage at the first input (21) and on a second voltage at the second input (22).

Abstract: A charging regulator arrangement (30) and a method for charging a battery (13) are specified. Current elements (11, 12) are produced by a DC/DC converter (14) and a series regulator (24). A control unit (15) controls the DC/DC converter (14) and the series regulator (24) as a function of the actual charging current (I) of the battery. The power losses can be reduced when the chip area is reduced, and this makes it possible to lengthen the life of the battery (13) to be charged. The disclosed technique is suitable, for example, for use in mobile radios.

Abstract: An apparatus includes a voltage converter for supplying voltage to an electrical load. The voltage converter is electrically connected at an output to a terminal of a series circuit. The voltage converter includes mechanisms for connecting the electrical load and a current sink. The voltage supplied by the voltage converter is dependent on an input voltage and on a present multiplication factor. The apparatus also includes a first comparator, a second comparator, and selection logic.

Abstract: A control arrangement (1) for a voltage converter for converting a first DC voltage (UBAT) into a second DC voltage (U-G) comprises a first input (3) that is provided for coupling to a means of sensing a first current (I1) on the primary side of the transformer (11). The output of the control arrangement (1) is coupled to a control terminal (17) of a transistor (16) that can be connected in series with the primary side of the transformer (11). The control arrangement (1) furthermore comprises a computing unit (2), provided for giving the transistor (16) a low value of resistance during a switched-on phase (T-ON), and a high value of resistance during a switched-off phase (T-OFF). The control arrangement (1) furthermore incorporates a first comparator (42) for comparing a value of the first current (I1), or a value derived from the value of the first current (I1), with an adjustable setpoint value (SO1).